The present invention includes a circuit which can achieve a 200 nano second write to read time. The present invention eliminates a switch in the RMR measurement circuit.
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1. A write to read switching circuit to switch from a write mode to a read mode comprising:
a head circuit to write and read information; an amplifier connected to said head circuit, a transconductional circuit directly connected to said amplifier, said transconductional circuit including a single pole, a reference generate circuit connected to internal ground, and a measurement circuit connected to said head circuit; wherein said head circuit switches from said write mode to said read mode.
2. A write to read switching circuit to switch from a write mode to a read mode as in
said write to read switching circuit further comprises a buffer circuit being connected between said transconductional circuit and said reference generate circuit.
3. A write to read switching circuit to switch from a write mode to a read mode as in
said buffer circuit indirectly connected to said internal ground.
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This application claims priority under 35 USC § 119(e)(1) of provisional application Ser. No. 60/080,983, filed Apr. 7, 1998.
The present invention relates to disc drive systems and more particularly for devices for a write to read switching circuit.
Magnetic disc drives have read/write heads out of which the write head portion is used for writing data to magnetic discs and the read head portion is used for reading data from the magnetic disc. During a write operation, a write signal is provided to a selected write head from a write control circuit. The write signal represents data to be encoded into the magnetic disc. More particularly, the write head receives encoded digital data from a "channel" circuit. The transitions of the signal received from the channel circuit causes the write current flowing within the write head to reverse direction which in turn, induces a flux reversal in the magnetized material of the medium of the magnetic disc.
During a read operation, the read head senses flux reversals from the magnetic disc. The flux reversals are encoded into magnetic disc during the write operation. Based on the flux reversals, the read head provides a read signal to a read channel. The read circuit amplifies the read signal, and the channel circuit recovers the data. The read circuit then provides the data to a magnetic disc controller for further processing.
Each magnetic disc in a disk drive has a corresponding "head" adjacent to the top and bottom surface of the disc. Thus, there are two heads per stack where N equals the number of disc in a drive. Normally, only one head is active at a given time in order to control these channels. Typically, each channel additionally includes a current path for current to flow to the MR head.
When switching from a write mode when the write circuit is activated to a read mode when a read circuit is activated, a write to read switching circuit is employed to assure that the transitions created by the change from the write mode to the read mode have been eliminated. One of the criterion of a write to read switching circuit is to minimize any delay associated with the write to read switching circuit.
One such write to read switching circuit is illustrated in FIG. 1. This circuit includes a head 100, which is connected to a Rmr measurement circuit 122. The RMR measurement circuit 122 includes a resistor 124 which is coupled to a FET 126 which is coupled to ground. This FET 126 controls the activation of the measurement circuit 122. However, the FET 126 requires a finite amount of time to switch the measurement circuit 122 and introduces noise to the write to read switching circuit. Additionally, the FET 124 shuts off the current to the Rmr measurement circuit 122 during write mode. However, when going. from write to read, the current begins to flow in the Rmr measurement circuit 122 causing a transient in the head circuit 100. This results in a longer time for the current to settle in the Rmr measurement circuit 122 causing additional delay in the write to read time.
Additionally,
Additionally, there is a further problem associated with the transconductance circuit 114. As illustrated in
The present invention includes a write to read switching circuit having a switching time of 200 nano seconds. This is because by the invention, the transients which are generated by switch from the write mode to the read mode are significantly reduced. The write to read switching circuit of the present invention eliminates the low pass filter which is connected to a transconductance circuit. Additionally, the present invention eliminates a switch in the Rmr measurement circuit and provides a switchless Rmr measurement circuit. Furthermore, the present invention provides a write to read switching circuit which only uses a internal ground as a reference. More specifically, the write to read switching circuit is directly connected to internal ground through a resistor which is connected to the reference voltage generator.
As illustrated in
During waiting and write to read transition, head circuit 200 picks up a glitch which generates a voltage from the emitter of transistor 202 with a respect to ground. This increases the voltage from resistor 228 to transistor 202 which causes a difference in voltage across the input of amplifier 208. The transconductance circuits 204 has a voltage potential across the inputs that consequently causes a current to be sunk by the transconducted circuit 214. This current flows from capacitor 232 which cause voltage in capacitor 232 to decrease. This reduces voltage across the head circuit 200 reduces the voltage difference across the amplifier 208 output. For above to happen smoothly without any ringing, a one pole write to read circuit is required. The present invention has only one pole G-MC. Additionally, the circuit is not connected to external ground. Furthermore, the circuit has a RMR measurement circuit with no switch. These give the fast 200 ns write to read switching time.
Ranmuthu, Indumini, Cho, Hae-Seok
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